Rolling Friction, Wear Characteristics and Damage Behaviors of Si3N4 Ceramic Bearing Balls
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Abstract
Compared with steel balls, Si3N4 ceramic bearing balls possess high revolution speed limit, high bearing capacity, resistance to high temperature and acid-base corrosion, together with certain self-lubricating properties, and are used as rolling bodies in high-speed bearings with absolute advantages and have became the key components of high-speed, high-precision bearings. In this paper, the rolling friction damage characteristics of Si3N4 ceramic bearing balls were studied by simulating the real motion of bearing balls in service conditions. The rolling friction wear state and surface damage behaviors of Si3N4 ceramic bearing balls against bearing steel raceways under non-lubrication and grease lubrication conditions were investigated, followed by analyzing the rolling friction damage behavior evolution laws and mechanisms of Si3N4 ceramic bearing balls. Results showed that the introduction of grease significantly reduced the rolling friction coefficient, particularly alleviated the fatigue damage behavior of Si3N4 ceramic bearing balls in rolling friction and wear processes. The rolling friction damage mechanisms of Si3N4 ceramic bearing balls were mainly fatigue damage, adhesive wear and accompanied by friction chemical reaction under non-lubrication condition. Mesh structural fatigue cracks in multi-scale were progressively formed during sliding and the cracks also extended to the inside of the Si3N4 ceramic bearing ball, resulting in the fatigue flaking among the cracks and cracking of grain boundaries. Meanwhile, amorphous structure appeared at the subsurface layer of the Si3N4 ceramic bearing ball under the action of friction. Under the grease lubrication condition, however, the rolling friction damage mechanisms of Si3N4 ceramic bearing balls were mainly abrasive wear and micro-brittle fracture. The damage behaviors evolved from scratches to willow-mounted micro-pits, which further increased and deepened, and brittle fracture was presented at the edges of the micro-pits. In this case, cracking of grain boundaries also existed at the subsurface layer of the Si3N4 ceramic bearing ball. Because grease alleviated the fatigue damage behavior, there were no amorphous structure and the cracks did not extend to the inside of the Si3N4 ceramic bearing ball.
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